EXPERIMENTAL STUDY OF SELF-SUFFICIENT PILOT-SCALE PYROLYSIS ON INSTANT NOODLE PLASTIC PACKAGING
The rapid economic and population growth are two factors of the increasing waste generation. Based on the conducted Municipal Solid Waste (MSW) composition survey, 15.7% of MSW contained plastic waste, in which 4.6% were Non Recycled Plastic (NRP). These NRP wastes accumulate in landfills due to...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/41698 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The rapid economic and population growth are two factors of the increasing waste
generation. Based on the conducted Municipal Solid Waste (MSW) composition
survey, 15.7% of MSW contained plastic waste, in which 4.6% were Non Recycled
Plastic (NRP). These NRP wastes accumulate in landfills due to the lack of
proper waste management. NRP waste problem arises, due to its low value,
making them unpopular material to be recycled. Pyrolysis process was proposed
in this research. Pyrolysis converts NRP waste into liquid fuel with high calorific
value. However, the energy sufficiency of the pyrolysis process to treat NRP
waste was still unknown.
A 100 L pilot-scale batch reactor was used to pyrolyze instant noodle plastic
packaging samples as a representative of NRP waste. Sample of 4.7 kg were
pyrolyzed using kerosene burner as the heating source in three processing
temperatures of 400 ?, 450 ?, and 500 ?, producing two distinctive pyrolytic
oils and condensed into two different temperatures. The heating values, oil yields,
and fuel consumptions were then used to define the recommended operating
temperature. The recommended temperature was found to be 500 ? as it had the
highest net energy produced from the process of 35.2 MJ. The heating values of
the pyrolytic oils from the first outlet and second outlet were found to be 46.86
MJ/kg and 45.86 MJ/kg, densities of 789.3 kg/m3 and 761.1 kg/m3, and kinematic
viscosities of 3.66 cSt and 1.51 cSt, respectively.
The obtained pyrolytic oils were then used as kerosene substitute for the
subsequent pyrolysis process. The result showed that applying the pyrolytic oil
sped up the process by 13.0%, and gained higher net energy than that of kerosene.
The system’s energy self-sufficiency was attainable as the net energy produced
totaled to 48.1 MJ. In the end, simple economic feasibility was conducted using
sensitivity analysis. It was revealed that the worker’s payroll had the largest effect
on cashflow. In order to achieve breakeven point, worker’s payroll needs to be
reduced by 84%, or increase the oil selling price to 382%, or increase the sales
volume to 504%. It can be concluded that the developed pyrolysis process could
be sustainable in the aspect of energy but still uneconomical.
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